RU16419U1 - ELECTRODE LIQUID HEATER AND ELECTRODE (OPTIONS) - Google Patents

Abstract

1. The electrode fluid heater, comprising a housing with a cover and at least two interacting electrodes, with current leads for connecting to an external electrical circuit, forming an internal electrical circuit with a heated fluid, characterized in that one or more, a thermistor with a positive temperature coefficient of resistance (posistor) and a given switching temperature. 2. The heater according to claim 1, characterized in that the posistor with a given switching temperature, one or more, is included in the internal electric circuit in series or parallel to one of the interacting electrodes. The heater according to claims 1 and 2, characterized in that the switching temperature of the posistor corresponds to the allowable temperature for heating the liquid. 4. The electrode containing several layers, one of which is provided with a current supply, and the other in contact with the heated liquid, is made in the form of a protective screen, characterized in that it further comprises a layer placed between them, made in the form of a posistor with a given switching temperature corresponding to the permissible heating temperature liquids. 5. An electrode according to claim 4, characterized in that the posistor layer is made of a rubber-like material with a positive temperature coefficient of resistance, for example, electrically conductive rubber with the inclusion of barium titanate (ВаТiO) .6. An electrode according to claim 4, characterized in that the posistor layer is made of ceramic made on the basis of a material with a positive temperature coefficient of resistance, for example barium titanate. The electrode according to claims 4-6, ex.

Description

ELECTRODE LIQUID HEATER AND ELECTRODE (OPTIONS)

The utility model relates to electrical engineering, namely, to electrode-type electric heaters and can be used for autonomous heating and hot water supply of facilities without centralized heat supply, for example, cottages, industrial and office premises, greenhouses, etc., as well as in thermostats and fluid heaters.

A known installation of electrode heating of a liquid containing electrodes with current leads connected through a switching device to an AC source. Power control in it is carried out using switching devices in manual or automatic mode (see AS USSR No. 1116562, class N05VZ / 60, 1982). The disadvantages of the known installation are the design complexity and high material consumption.

Known electrode fluid heater, adopted for the prototype, comprising a housing with a cover and at least two interacting electrodes with current leads, for connection with an external electrical circuit, forming an internal electrical circuit with the heated fluid.

N05VZ / 60 F24H 1/20

In this case, the electrodes are connected to current leads through bimetallic plates (see AS USSR No. 1045421, class Н05В 3/60, 1982).

The power regulation in the known heater is carried out by changing the resistance of the liquid in the internal electric circuit when the interacting electrodes diverge or converge, carried out by bimetallic plates, when the temperature of the liquid changes, i.e. automatically. Since when the electrodes diverge or converge, both the length and the cross-sectional area of the liquid column between them change.

A disadvantage of the known heater, and more specifically the technical solution implemented in it, is that during operation the parallelization of the interacting electrodes is not ensured and, therefore, the current density along the length of the electrodes is unstable, which negatively affects its performance. Also, in the known heater, the task of protecting the liquid from overheating, i.e. heating above the permissible temperature due to safe operation.

It is well known that with an increase in water temperature from 0 to 100 ° C, its electrical conductivity increases by 3 .. .5 times, leading to the same increase in heat dissipation power, at a constant voltage on the electrodes. And this is a condition sufficient for the instability of the heating system (the main area of application of electrode fluid heaters) to occur due to the periodic brewing of the boiler. Therefore, special measures are required to prevent the boiler from accelerating when the temperature in the heating system rises. It can be: electric systems of voltage regulation on electrodes; tkscheratury control systems in

characteristic points in conjunction with power-off systems for a given temperature setting, etc.

It is desirable to have an electrode fluid heater devoid of the above disadvantages.

This is achieved by the fact that in the electrode fluid heater, comprising a housing with a cover and at least two interacting electrodes with current leads, for connecting to an external electrical circuit, forming an internal electrical circuit, according to a utility model, to an internal electrical circuit in addition to an internal electrical circuit one or more thermistors are included with a positive temperature coefficient of resistance (posistor) and a predetermined switching temperature (in another terminology, a given Curie point).

In this case, a posistor, with a given switching temperature, one or more (depending on the task), can be included in the internal electrical circuit in series or parallel to one of the interacting electrodes, and the switching temperature of the posistor corresponds to the allowable temperature of the heating fluid.

The inclusion of a posistor, one or more, with a given switching temperature, in the internal electric circuit of an electric liquid heater, parallel or sequentially to one of the interacting electrodes, ensures the passage of electric current, and, consequently, heating of the liquid in this section of the internal electric circuit only to a certain temperature determined by the switching temperature of the posistor, corresponding, for example, to the permissible temperature of the heating fluid. Since it is known that the dependence of the resistance of the posistor on temperature, as well as

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the steepness of the region with a positive temperature coefficient of resistance (with a positive TCS) can vary over a very wide range. And in the area with a positive TCS starting at the switching point, the resistance logarithm is approximately proportional to the temperature:

LogR AT + A, where A and A are constants; R is the resistance of the posistor; T is the temperature of the posistor.

At the same time, the characteristics of the posistors are very stable - 5000 hours, and the switching temperature is stable within + 1 ° C (see E.D. Macklin Thermoresistors, M. Radio and Communications, 1983, fig. 11.6 p. 151, formula 11.1, p. . 151 and p. 156. ..158).

In the aggregate, the features of the utility model allow: guaranteed, in automatic mode, heating the liquid in the heater to a certain, predetermined temperature;

-to simplify the design of the heater, given the absence of the need for a complex control system for its operation;

-to increase the reliability of the heater, due to the lack of movable elements in its design.

The technical solutions underlying the claimed electrode fluid heater can be implemented by using electrodes of various designs, depending on the requirements for the heater. Therefore, utility models are claimed together in one application.

As a prototype for an electrode used in a heater heating a liquid to a certain temperature, an electrode is selected that is part of a device for heating a liquid, containing

several layers, one of which is equipped with a current supply, and the other, in contact with the heated liquid, is made in the form of a protective screen (AS USSR No. 430520, class Н05В 3/78, (F24H 1/20), 1972).

A disadvantage of the known electrode is that it is unable to independently limit the current passing through itself when the heated fluid reaches the maximum allowable heating temperature.

It is desirable to have an electrode for an electrode fluid heater devoid of the above drawback, i.e. able to limit the current passing through itself, when the heated fluid reaches the set temperature.

This is achieved by the fact that the known electrode containing several layers, one of which is provided with a current supply, and the other in contact with the heated liquid, is made in the form of a protective screen, according to a utility model it further comprises a layer placed between them, made in the form of a posistor with a given switching temperature (in another terminology, the Curie point) corresponding to the allowable temperature of the heating fluid.

In this case, the posistor layer can be made, for example, of a rubber-like material with a positive TCR, for example, electrically conductive rubber with barium titanate (BaTiuz), or of ceramics made on the basis of a material with a positive temperature coefficient of resistance, for example, also barium titanate. And it is connected with the layers between which it is located, with a substance with good electrical conductivity, for example, silver paste, and the protective screen layer is additionally endowed with the function of a radiator.

The implementation of the additional layer placed between the layers with a current supply and a layer in contact with the heated fluid and

made in the form of a protective screen, as a posistor with a given switching temperature corresponding to the permissible temperature of the liquid heating, it stops the passage of electric current through the electrode and, therefore, stops the heating of the liquid when it reaches a temperature corresponding to the switching temperature of the posistor, which is selected in advance.

The implementation of a posistor layer of rubber-like material with a positive TCR, for example, conductive rubber with the inclusion of barium titanate (ВаТЮ3), allows us to simplify the manufacturing technology of the electrode, especially a cylindrical shape.

If necessary, the posistor layer can be made of ceramics made on the basis of barium titanate (BaTiuZ) with the addition of other elements, or based on silicon, germanium, etc.

The connection of the porous layer with the layers between which it is located, with a substance with good electrical conductivity, such as silver paste, provides good heat removal from the posistor, increasing its reliability and durability, which is also facilitated by a protective screen, additionally endowed with the function of a radiator.

As a prototype for an electrode used in a heater with posistors, with a given switching temperature, included in the internal electrical circuit of the heater in series with one of the electrodes and parallel to each other, and with heating the liquid in a given mode to a given temperature, the electrode included in the electrode a boiler containing sections with current leads separated by insulators (A.S. No. 2062960, class F24H 1/20, 1993).

In the known device, the power is regulated by switching sections from star to triangle and vice versa, and, consequently, by changing the magnitude of the current passing through the sections of the electrode and the heated fluid.

However, such switching is performed manually on the disassembled device, which is its drawback.

In addition, the use of the known electrode does not provide protection for the heated fluid from overheating, boiling, which leads to unstable operation of the heating device as a whole.

It is desirable to have an electrode for an electrode fluid heater eliminating the need for external regulation of the amount of current passing through it, providing the necessary heating mode and reliably protecting the heated fluid from overheating, i.e. heating above the permissible, pre-set temperature.

This is achieved by the fact that in the known electrode containing sections with current leads, separated by insulators, according to the utility model, the sections are made in cross section of several layers, one of which is a posistor with a given switching temperature corresponding to the allowable temperature of the heating fluid on the side surface sections. In this case, the posistor layer is located between the layer with the current supply and the layer in contact with the heated fluid and acting as a protective shield and radiator. In all cases, the posistor layer is connected with the layers between which it is located, by a substance with good electrical conductivity, for example, silver paste.

The location of the posistor layer between the layer connected to the current lead and the layer in contact with the heated fluid and acting as a protective shield and radiator provides reliable protection against electrochemical corrosion and good heat removal from the posistor and, therefore, durability and reliability.

Correspondence of the switching temperature of the posistor layer of the sections to the permissible temperature of the heating fluid provides, taking into account the temperature gradient of the heated fluid along the length of the electrode, i.e. in sections, sequential self-shutdown of sections, as the fluid washing them to an acceptable temperature, which eliminates overheating of the heated fluid.

The connection of the posistor layer with the layers between which it is located, using a substance with good electrical conductivity, such as silver paste, provides the required temperature and, therefore, durability and reliability.

As a prototype for an electrode used in a heater with posistors, with a given switching temperature, included in the internal electric circuit of the heater parallel to the electrode and each other, with heating the liquid in a given mode and ensuring constant liquid circulation in the heating circuit, the electrode included in the composition of the electrode boiler, containing sections with current leads, separated by insulators (AS No. 2062960, class F24H 1/20, 1993).

In the known device, the power is regulated by switching the electrode sections from star to triangle and vice versa, and, consequently, by changing the amount of current passing through the electrode sections and the heated fluid in manual mode, which is its drawback.

It is desirable to have an electrode for an electrode fluid heater that eliminates the need for external regulation of the amount of current passing through it and provides both protection of the heated fluid from overheating and constant fluid circulation in this & KS) 46QI

heating, which increases the reliability and efficiency of the entire heating system as a whole.

This is achieved by the fact that in an electrode containing sections with current leads, separated by insulators, according to a utility model, part of the sections is made, in cross section, of several layers, one of which is a posistor with a given switching temperature corresponding to the allowable temperature of the heating fluid on the side surface of the section , and the other part of the sections, at least one, is made without a posistor layer. In this case, the posistor layer is located between the layer with the current supply and the layer in contact with the heated fluid and acting as a protective shield and radiator. In all cases, the posistor layer is connected with the layers between which it is located, by a substance with good electrical conductivity, for example, silver paste.

The implementation of part of the sections, in cross section, of several layers, one of which is a posistor with a given switching temperature corresponding to the allowable temperature of heating the liquid on the side surface of the section, and the other part of the sections, at least one, is made without a posistor layer, provides the practical termination of the passage of electrical current through the posistor sections and, therefore, the heated fluid, upon reaching the temperature heated by the fluid, corresponding to the switching temperature of the posistor selected in advance, and the continuation of the passage of part of the electric current through other sections made without a posistor layer, which ensures uninterrupted fluid circulation in the heating system.

acting as a protective shield and radiator, it provides reliable protection against electrochemical corrosion and good heat removal from the posistor and, therefore, durability and reliability.

Correspondence of the switching temperature of the posistor layer of the individual sections to the permissible temperature of the heating fluid provides, taking into account the temperature gradient of the heated fluid along the length of the electrode, i.e. in sections, successive self-shutdown of sections, as the liquid washing them reaches an acceptable temperature, which eliminates overheating of the heated liquid, since only the part of the current necessary to ensure circulation is passed through the section without a posistor layer.

The connection of the posistor layer with the layers between which it is located, using a substance with good electrical conductivity, such as silver paste, provides the required temperature and, therefore, durability and reliability.

In FIG. 1 shows the electrical schematic diagram of the heater when a single posistor is connected in series to the internal electric circuit. In FIG. 2 - shows the electrical circuit diagram of the heater when several posistors are connected in series to one of the electrodes and parallel to each other in the internal electric circuit. In FIG. Figure 3 shows the electrical circuit diagram of the heater when several posistors are connected in parallel to the electrode and to each other in the internal electric circuit. In FIG. Figure 4 shows the characteristic dependence of the resistance of the posistor on temperature (E.D. Macklin Thermistors, M. Radio and Communications, 1983., Fig. 11.6, p. 151). In FIG. 5 shows an electrode fluid heater, which implements the electrical circuit diagram shown in figure 1, with an electrode, realatoSOVfOf

ten

This scheme (in the context). In FIG. 6 shows the electrode that implements the circuit diagram of the heater shown in figure 2. In Fig.7 shows the electrode that implements the circuit diagram of the heater shown in Fig.Z. In FIG. 8 shows a view of I in figures 5, 6 and 7.

The electrode fluid heater (see figures 1, 2, 3, and 5) contains a housing 1 with a cover 2 and nozzles for supplying fluid 3 and fluid outlet 4. (Depending on the task to be solved, housing 1 can be a heating boiler, a thermostat, a fluid heater, and etc.). 5- zero electrode, with resistance Rgo, the function of which can also be performed by the zeroed housing 1. 6-phase electrode, with resistance KEF. (The number of electrodes in the heater can be any, but the smallest number of interacting electrodes is two). 7 - current supply of the zero electrode 5, and 8 - current supply of the phase electrode 6.9 liquid, with resistance Кж. 10 - posistor with a given transition temperature and resistance R posistor layer. 11- grounding, 12 protective cover. 13 is a combined electrode (see Fig. 5), which is a combination of an electrode 6 with a posistor 10. The combined electrode is isolated from the nullified housing 1 (see figures 5, 6 and 7) by means of the lower insulator 14 and the upper insulator 15.

In the embodiment of the heater according to FIG. 5, the combined electrode 13 comprises a current supply layer 16 with a current supply 8 and a protective screen layer 17, additionally performing the function of a heat radiator, between which there is a posistor layer (posistor) 10 made of either rubber-like material or porosity ceramic. In this case, the posistor layer, the posistor,

10 is connected with layers 16 and 17 by an electrically conductive layer 18 (see FIG. 8) made, for example, of silver paste.

In the embodiment of FIG. 6, the combined sectional electrode 19 contains sections 20, 21 and 22, separated by insulators 23, with a common current supply 8. Each section 20,21 or 22 contains a current supply layer 16, a resistive layer 10 and an outer protective screen layer - a radiator 17, interconnected electrothermal conductive layer 18 (see Fig. 8).

In the embodiment of FIG. 7, the combined sectional electrode 24 consists of a section 25.26 containing a posistor layer 10 and sections not containing a posistor layer 10, in our example it is section 27. The posistor-containing sections 25 and 26 consist (see Fig. 8) of the current-conducting layer 16, a posistor layer 10, a protective screen layer 17, which is at the same time a radiator, and electrothermally conductive layers 18 connecting them.

The electrode fluid heater, in which one of the circuit diagrams shown in figures 1, 2 and 3 is implemented, by using the electrodes shown in figures 5, 6 and 7, respectively, operates as follows.

When the heater is initially turned on (see, for example, Fig. 1 and Fig. 5), the voltage is supplied through an external electric circuit to current leads 7 and 8 and through them to electrodes 5 and 6, respectively. Between the electrodes 5 (1) and 6 (13), an electric current flows through the heated liquid 9 and the resistor 10, the parameters of which depend on the voltage between the electrodes 5 and 6, the resistance Ql of the liquid column 9 between them and the resistance Rn of the resistor 10. At room values temperature, the resistance value of the posistor 10 lies in the range of units of Ohms. The voltage drop on it is small, so the power

No. 0JWM I

12

allocated to the posistor 10 is small, and does not affect the amount of current in the internal circuit. As the liquid 9 heats up, the posistor 10 also heats up. Moreover, its resistance (see Fig. 4) even drops somewhat. However, when the heated fluid 9, circulating in the heating system, and, therefore, the posistor 10, reaches the temperature corresponding to the switching temperature (point Тп on the graph in Fig. 4, chosen in advance), in our case it is a temperature of 95 ° С, lower than the boiling point of the liquid, in the posistor 10, the rate of change of resistance sharply increases. Namely, the resistance begins to increase by orders of magnitude, which leads to a sharp increase in the voltage drop across the posistor 10. The heated liquid 9 cannot remove the heat released in the posistor 10, because it is already heated to a predetermined temperature, determined by the switching temperature of the posistor 10, and in the posistor 10 the self-heating process begins. Those. when the switching temperature is reached, the posistor 10 sharply reduces the current through itself, to the value of maintaining the state of self-heating. In practice, this means the termination of heating of the liquid. The return to the initial state (liquid heating state) is possible only when the temperature of the heated liquid 9 decreases below the permissible temperature and, therefore, the posistor 10 to a value lower than the switching temperature.

Thus, it is provided that the liquid is heated to a predetermined temperature automatically, which can provide the utility model with widespread use in all kinds of electrode-type heating devices.

In the heater made according to the circuit of FIG. 2 using an electrode made according to FIG. 6, the established mode of heating the liquid 9 is provided by selecting posistors 10 with certain switching temperatures.

When applying voltage to the electrode 6 (24), which is part of the electrode fluid heater (not shown) and, naturally, in interaction with another electrode 5 (1), electrically connected with it, located in the heated fluid, the temperature of which is lower than the switching temperature posistor layers 10 sections 20, 21 and 22, through it passes an electric current heating the liquid. The parameters of the flowing electric current depend mainly on the voltage between the electrodes, the resistance of the posistor layers 10 of the sections 20, 21 and 22 and the resistance of the liquid. At room temperature values, the resistance value of the posistor (see Fig. 4) lies in the region of units of Ohms. The voltage drop across the posistor layer of 10 sections 20.21 and 22 is small, the power emitted by it is small and is easily removed by the protective layer - screen - radiator 17 and does not particularly affect the amount of current in the circuit. As the fluid heats up, the posistor layers 10 of the sections 20.21 and 22 also heat up, while their resistance even slightly decreases at first. But when the switching temperature (point Tn on the graph in Fig. 4) is reached, which is selected constructively, in our case it is 95 ° C, in the posistor layer 10, first section 20, the rate of resistance change sharply increases, by orders of magnitude. And the posistor layer 10 of section 20 is locked. Since the heated fluid cannot cool the posistor layer 10, because it itself is already heated to a temperature corresponding to the switching temperature. Those. when the switching temperature is reached, the posistor layer 10 sharply reduces the current through itself to the value of maintaining self-heating. And this, in practice, means the cessation of heating liquid $ M Ш01

14

section 20 until its temperature drops below the switching temperature of the posistor layer 10.

With further heating of the liquid by sections 21 and 22 remaining in operation, the lower boundary of the liquid layer heated to an acceptable temperature, under certain circumstances, may drop, capturing section 21 as well. In this case, the posistor layer 10 of section 21 is locked, similar to locking the posistor layer 10 sections 20. Now sections 20 and 21 will no longer participate in the heating of the liquid. Section 22 can also turn off self-similarly. When cooling the liquid washing sections 20, 21 and 22 below the temperature corresponding to the switching temperature of the posistor layer 10, section, first section 22, then, if cooling continues, section 21, then section 20, are included in the work in turn. Those. the electrode is capable of reaching steady state operation itself.

Thus, the electrode provides heating of the liquid to a predetermined temperature and maintains a predetermined mode of operation independently, automatically, which can provide it with widespread use in all kinds of electrode-type heating devices.

In the heater made according to the circuit of FIG. 3 using an electrode made according to FIG. 7, the established mode of heating the liquid 9 is ensured with the constant circulation of the heated liquid by combining sections 25 and 26 containing posistors 10, with certain switching temperatures, with section 27 not containing a posistor layer. The operation of this heater is similar to the operation of the heater described above, with the difference that when heating the liquid 9 and locking the posistor layers 10, posistor-containing sections 25 and 26, the section 27 that does not contain the posistor layer works constantly, providing the necessary heating of the liquid and its circulation in the heating system .

Thus, the use of the inventive electrode in an electrode fluid heater, for example, for circulating water heating systems, allows you to warm up the room in a short time, reduce power consumption and automatically reach stable temperature maintenance, while ensuring constant fluid circulation in the system, which can provide it widespread use.

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Claims (13)

1. The electrode fluid heater, comprising a housing with a cover and at least two interacting electrodes, with current leads for connecting to an external electrical circuit, forming an internal electrical circuit with a heated fluid, characterized in that one or more, a thermistor with a positive temperature coefficient of resistance (posistor) and a given switching temperature.  2. The heater according to claim 1, characterized in that the posistor with a given switching temperature, one or more, is included in the internal electrical circuit in series or parallel to one of the interacting electrodes.  3. The heater according to claims 1 and 2, characterized in that the switching temperature of the posistor corresponds to the allowable temperature for heating the liquid.  4. The electrode containing several layers, one of which is equipped with a current supply, and the other in contact with the heated fluid is made in the form of a protective screen, characterized in that it further comprises a layer placed between them, made in the form of a posistor with a given switching temperature corresponding to the permissible fluid heating temperature. 5. The electrode according to claim 4, characterized in that the posistor layer is made of a rubber-like material with a positive temperature coefficient of resistance, for example, conductive rubber with the inclusion of barium titanate (ВаТiO ₃ ).  6. The electrode according to claim 4, characterized in that the posistor layer is made of ceramic made on the basis of a material with a positive temperature coefficient of resistance, for example barium titanate.  7. The electrode according to claims 4 to 6, characterized in that the posistor layer is connected with the layers between which it is located, with a substance with good electrical conductivity, for example, silver paste, and the protective screen layer is additionally endowed with the function of a radiator.  8. An electrode containing sections with current leads separated by insulators, characterized in that the sections are made in cross section of several layers, one of which is a posistor with a given switching temperature corresponding to the allowable temperature of the heating fluid on the side surface of the section.  9. The electrode of claim 8, characterized in that the posistor layer is located between the layer connected to the current supply and the layer in contact with the heated fluid and acting as a protective shield and radiator.  10. The electrode according to claims 8 and 9, characterized in that the posistor layer is connected to the layers between which it is located with a substance with good electrical conductivity, for example, silver paste.  11. An electrode containing sections with current leads, separated by insulators, characterized in that part of the sections is made in cross section of several layers, one of which is a posistor with a given switching temperature corresponding to the allowable temperature of the heating fluid on the side surface of the section, and the other part of the sections, at least one, is made without a posistor layer.  12. The electrode according to claim 11, characterized in that the posistor layer is located between the layer connected to the current supply and the layer in contact with the heated fluid and acting as a protective shield and radiator. 13. The electrode according to PP.11 and 12, characterized in that the posistor layer is connected with the layers between which it is located, a substance with good electrical conductivity, for example, silver paste.